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Examining Historical and Current Mixed-Severity FireRegimes in Ponderosa Pine and Mixed-Conifer Forests ofWestern North AmericaDennis C. Odion1,2*, Chad T. Hanson3, Andre Arsenault4, William L. Baker5, Dominick A. DellaSala6,
Richard L. Hutto7, Walt Klenner8, Max A. Moritz9, Rosemary L. Sherriff10, Thomas T. Veblen11,
Mark A. Williams12
1 Earth Research Institute, University of California Santa Barbara, Santa Barbara, California, United States of America, 2 Environmental Studies Department, Southern
Oregon University, Ashland, Oregon, United States of America, 3 Earth Island Institute, Berkeley, California, United States of America, 4 Canadian Forest Service Natural
Resources Canada, Corner Brook, N.L., Canada, 5 Program in Ecology and Department of Geography, University of Wyoming, Laramie, Wyoming, United States of America,
6 Geos Institute, Ashland, Oregon, United States of America, 7 Avian Science Center, Division of Biological Sciences, University of Montana, Missoula, Montana, United
States of America, 8 Wildlife Habitat Ecologist, FLNR, Thompson-Okanagan Region, Kamloops, B.C., Canada, 9 Ecosystem Sciences Division, Environmental Science, Policy,
& Management Dept., University of California, Berkeley, California, United States of America, 10 Department of Geography, Humboldt State University, Arcata, California,
United States of America, 11 Department of Geography, University of Colorado Boulder, Boulder, Colorado, United States of America, 12 Program in Ecology and
Department of Geography, University of Wyoming, Laramie, Wyoming, United States of America
Abstract
There is widespread concern that fire exclusion has led to an unprecedented threat of uncharacteristically severe fires inponderosa pine (Pinus ponderosa Dougl. ex. Laws) and mixed-conifer forests of western North America. These extensivemontane forests are considered to be adapted to a low/moderate-severity fire regime that maintained stands of relativelyold trees. However, there is increasing recognition from landscape-scale assessments that, prior to any significant effects offire exclusion, fires and forest structure were more variable in these forests. Biota in these forests are also dependent on theresources made available by higher-severity fire. A better understanding of historical fire regimes in the ponderosa pine andmixed-conifer forests of western North America is therefore needed to define reference conditions and help maintaincharacteristic ecological diversity of these systems. We compiled landscape-scale evidence of historical fire severity patternsin the ponderosa pine and mixed-conifer forests from published literature sources and stand ages available from the ForestInventory and Analysis program in the USA. The consensus from this evidence is that the traditional reference conditions oflow-severity fire regimes are inaccurate for most forests of western North America. Instead, most forests appear to havebeen characterized by mixed-severity fire that included ecologically significant amounts of weather-driven, high-severityfire. Diverse forests in different stages of succession, with a high proportion in relatively young stages, occurred prior to fireexclusion. Over the past century, successional diversity created by fire decreased. Our findings suggest that ecologicalmanagement goals that incorporate successional diversity created by fire may support characteristic biodiversity, whereascurrent attempts to ‘‘restore’’ forests to open, low-severity fire conditions may not align with historical reference conditionsin most ponderosa pine and mixed-conifer forests of western North America.
Citation: Odion DC, Hanson CT, Arsenault A, Baker WL, DellaSala DA, et al. (2014) Examining Historical and Current Mixed-Severity Fire Regimes in Ponderosa Pineand Mixed-Conifer Forests of Western North America. PLoS ONE 9(2): e87852. doi:10.1371/journal.pone.0087852
Editor: Paul Adam, University of New South Wales, Australia
Received July 26, 2013; Accepted January 1, 2014; Published February 3, 2014
Copyright: � 2014 Odion et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permitsunrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Funded by Environment Now (http://www.environmentnow.org/). The funders had no role in study design, data collection and analysis, decision topublish, or preparation of the manuscript.
Competing Interests: The authors have declared that no competing interests exist.
* E-mail: [email protected]
Introduction
In just two days in 1910, 1.2 million ha of forestlands in Idaho
and Montana in the western USA burned in a massive fire driven
by exceptional winds [1]. In the aftermath, the United States
instituted a policy of aggressive fire suppression [2]. Decades of fire
suppression activities since 1910 have reduced the extent and
number of wildfires in the USA, as well as parts of Canada. There
is now widespread concern that fire exclusion has caused
vegetation in western North America to be much more susceptible
to uncharacteristically severe fire. This concern is greatest in the
extensive, often drier forests of the North American Cordillera,
especially those dominated by ponderosa pine (Pinus ponderosa
Dougl. ex. Laws) and Jeffrey pine (P. jeffreyi Grev. & Balf.), or those
mixed with ponderosa/Jeffrey-pine and other conifer species
(hereafter ponderosa pine and mixed-conifer forests of western
North America, defined in Table 1 and further described in
Methods).
The ponderosa pine and mixed-conifer forests of western North
America have traditionally been considered adapted to a low- or
low/moderate-severity fire regime (see Tables 1 and 2 for
definitions of fire terms) [3–8]. There have been many large
mixed-severity fires in western North America in recent years [9]
that have helped create widespread concern that fire exclusion has
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caused an unprecedented threat of uncharacteristically severe fires
[6–15]. Concomitantly, however, there has been increasing
recognition that fires in ponderosa pine and mixed-conifer forests
of western North America were also mixed in severity prior to any
significant effects of fire exclusion (Table 2) [16,17]. It has also
been increasingly recognized that these forests support biota that
are not adapted to low/moderate-severity fire, but rather are
dependent on the high-severity fire component of mixed-severity
regimes [18–22]. Thus, a better understanding of historical (i.e.,
generally prior to fire suppression and timber harvesting) fire
regimes in these forests is needed to define reference conditions
and maintain characteristic ecological diversity.
In recent decades, to address the widespread concerns about
uncharacteristically severe fire in western North America, fuel
reduction treatments have been implemented on millions of
hectares of ponderosa pine and mixed-conifer forests at a cost of
billions of dollars [23]. These treatments consist mainly of
harvesting smaller trees to reduce forest density [8], but larger
trees are typically harvested as well for economic reasons [24].
These treatments can negatively affect fire dependent species. For
example, the Black-backed Woodpecker (Picoides arcticus), an
imperiled fire-dependent species, largely avoids previously thinned
forest areas burned at high-severity [18]. Thinning treatments also
eliminate/degrade dense forest, which many species need,
including the Northern Spotted Owl (Strix occidentalis caurina), a
Threatened Species under the USA Endangered Species Act [25],
and the Pacific fisher (Pekania pennanti), a Candidate Species under
the USA Endangered Species Act [26]. In addition, forest thinning
treatments often require the reopening or construction of access
roads, which have many ecosystem impacts [27], and both the
thinning treatments and roads promote the establishment of
invasive species [27,28]. Thinning ultimately exacerbates fire
suppression impacts if it facilitates fire control, or if it becomes a
prerequisite for allowing wildfires to burn [13,29]. Thus, there is a
need to ensure that actions are ecologically justified.
Most descriptions of the fire regimes that characterize the
ponderosa pine and mixed-conifer forests of western North
America (e.g., [5–7,11]) emphasize how low-severity fires maintain
forests dominated by relatively old and large, fire-resistant trees,
with few understory trees, dead or dying trees, or shrubs [3–7,11–
13] (Table 2). Park-like conditions and low fuel loads are thought
to result from effects of frequent surface fire, which kills young,
fire-sensitive trees, while older, fire-resistant trees survive
[4,6,7,11,12].
In contrast, mixed-severity fire regimes are characterized by
more variable fire and forest structure across a wide range of
spatial and temporal scales [17,21] (Tables 1 and 2). The creation
of complex early seral vegetation by high-severity fire often occurs
in irregular patches across the landscape and at irregular intervals
[30]. Over time, the complex early successional vegetation created
by fire, if not reburned, transitions to mid- and then late-
successional forest, often containing pre-disturbance legacies, such
as standing or fallen dead trees and often some fire resistant, large
trees that survive fire crown fire (e.g., [31]). Thus, mixed-severity
fire regimes create complex successional diversity high beta
diversity, and diverse stand-structure across the landscape
[17,21,30,32–35].
The concepts and nomenclature used to describe fire regimes in
western North America can be ambiguous. Part of the problem
with defining fire regimes for the drier forests of western North
America is the classification of fire regimes into distinct categories
of low-, mixed-, and high-severity [5], or low/moderate-severity
Table 1. Definitions of terms as used in this paper.
Term Definition
Ponderosa pine andmixed-conifer forests ofWestern North America
Low- to mid-elevation, montane, non-coastal forests of western North America where a regime of low/moderate-severity fire (see Table 2for explanation) that limit tree recruitment has traditionally been applied. These extensive forests are dominated by ponderosa pine (Pinusponderosa), Douglas-fir (Pseudotsuga menziesii) and fir (Abies concolor and A. grandis) (see Methods). These forests are drier than coastalforests or most forests at higher elevations, though one region, the Klamath, is more mesic.
Fire dependent Biota that occur most abundantly after high-severity fire, and which are largely or entirely absent where high-severity fire has not occurredfor a long period.
Fire regime The frequency, size, seasonality, impacts and other characteristics of naturally occurring fires that have occurred in a vegetation type overits lifespan, generally 1–3 millennia [133].
High-severity fire rotation(or moderate to high-severity fire rotation)
The length of time required for an area equal to the area of interest to burn [134]. For high-severity fire, this is calculated as the time periodover which high-severity fire (or moderate- and high severity fire combined) is observed, divided by the proportion of the area of interestthat burns in that time period at high- or moderate/high-severity.
High-severity fire Fire that burns on the ground surface, and typically in the overstory canopy (crown fire) as well. Mortality of woody species as measured bybasal area is generally .70%. However, sprouting canopy species, such as oaks (Quercus spp.) typically survive these fires. High-severity firemainly occurs in relatively discrete patches under high winds that cause blow ups in fire behavior [108]. These patches range in size fromthe area occupied by a small group of trees to many thousands of ha in size, as in the case of the 1910 fires.
Low-severity fire Fire that burns on the ground surface such that relatively little or no mortality of live, standing vegetation occurs. Mortality of woodyspecies as measured by basal area is 0–20%, but is mostly 0–5%. See Table 2 for a detailed explanation of the effects of a regime of low-severity fire.
Moderate-severity fire Fire that burns only on the ground surface and that has effects that are intermediate between low- and high-severity fire as defined here.Mortality of woody species as measured by basal area is generally 20–70% within a given area.
Mixed-severity fire Fire that includes low-, moderate-, and high-severity effects. See Table 2 for a detailed explanation of the effects of a regime of mixed-severity fire.
Park-like forest A forest of widely-spaced live, mature trees and very few, if any, dead trees (snags). The understory is open, often dominated bybunchgrasses, and is mostly lacking woody plants.
Stand age The age within a stand of the dominant overstory canopy vegetation that recruited more or less as a cohort, typically after a previousdisturbance.
These terms may have different meanings in the literature depending on the context in which they are used.doi:10.1371/journal.pone.0087852.t001
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and high-severity [9], when nearly all fire regimes include a mix of
all three severities. Greater clarity in terminology is needed to
improve communication about fire regimes. Tables 1 and 2
document the terminology used herein.
In addition to unclear terminology, other factors create
difficulties for identifying which historical (i.e. prior to fire
exclusion) fire regime applies to a particular forest region. Where
fire has been excluded from a mixed-severity landscape for 100
years, early- and mid-successional patches created by high-severity
fire become late-successional patches, making it more likely that
these patches, indicative of a mixed–severity regime, will be
undetected. For example, high-severity fire patches may be
detected in old but not recent aerial imagery [35]. A primary
source of data on historical fires are scars in the growth rings of
surviving trees damaged by fire, which can provide annually
precise dates for past fires at the sampled locations [36–40].
However, these methods cannot effectively determine past
occurrence of high-severity fire. Thus, additional evidence is
needed to characterize historical fire regimes over more extensive
areas.
The US Forest Service Inventory and Analysis (FIA) program
provides an extensive dataset that is a probabilistic sample of forest
structure in large landscapes. This dataset allows for landscape-
scale inference and statistical analyses of forest age and structure
parameters consistent with a low- or mixed-severity fire regime.
Using the FIA data, and published sources of landscape-scale
(area of inference .25,000 ha) data, our objectives were to
address two broad questions: (1) How prevalent were mixed-
Table 2. Characteristics of fire regimes in ponderosa pine and mixed-conifer forests of Western North America.
Low/moderate-severity model Mixed-severity model
Tree populations 1. Stable. Gap phase recruitment dynamics. 1. Unstable. Gap and stand-level mortality and recruitment. Stand-replacementfires at intervals often shorter than tree lifespans.
2. Recruitment limited by frequent fire. 2. Recruitment abundant and stimulated by fire.
3. Resistant to fire (though oftendescribed as ‘‘fire-resilient’’).
3. Resilient following fire.
Landscape patterns 1. Successional diversity low. 1. Successional diversity high.
2. Gradual variation alongenvironmental gradients.
2. Variation along environmental gradients interrupted by sharp boundaries andpatchiness.
3. Low contrast heterogeneity.Intensity/complexity ofspatial pattern is low.
3. High contrast spatial heterogeneity. Intensity/complexity of spatial pattern ishigh.
4. Low beta diversity. 4. High beta diversity.
Stand structure 1. Does not vary markedly over time. 1. Varies markedly as a function of time since fire disturbance.
2. Open canopy of mature, medium andlarge trees; density low.
2. Variable canopy, tree size, and density variable; even-aged cohorts stimulatedby fire.
3. Understory with few trees or shrubs. 3. Understory varies.
Fire behavior 1. Typically low intensity surface firewith flame lengths ,3 m;short residence time.
1. Variable intensity surface or crown fire, variable residence time.
2. Fuel limited. Crown fire cannot initiate. 2. Not necessarily fuel limited. Crown fire can initiate under extreme conditions.
Individual firecanopy mortality
1. Mortality of canopy trees ,20% by basal area. 1. Mix of low-, intermediate- and high-severity fire with (0–20%, 20–70%, .70%)mortality of canopy trees by basal area respectively.
Interactive effects of fire onfuels and forest flammability
1. Fires continuously limit fuels and fire sensitivetrees.
1. Fires only temporarily lower fuels.
2. Maintain low flammability and forestmortality over time.
2. Do not maintain low flammability and forest mortality, except initially after fires.
Evolutionary responses 1. Fire resistant trees. 1. Fire resistant and fire-dependent or specialized biota. The latter includes specieswith reproduction timed to coincide with fire via fire-cued germination, fire‘‘embracer’’ plant species, and post-fire insect and bird specialists).
Fire exclusion leads to 1. High tree regeneration*. 1. Low tree regeneration.
2. Greatly increased flammability. 2. Small changes in flammability (vegetation is continuously flammable exceptinitially after fire).
3. Increased forestsusceptibility to mixed-severity fire.
3. Decreased susceptibility to mixed-severity fire.
Carbon storage1 1. Low-moderate; considerably lower than carryingcapacity.
1. Moderate to high; Near carrying capacity.
Fuel treatments (forestthinning)
1. Restores forest tree structure and fuelloads where infill associated withfire exclusion is removed.
1. May create uncharacteristic structure and composition (reduction in small andintermediate and some overstory trees, shrubs, down wood).
2. Increase open forest (woodland) biota. 2. Decrease in dense forest biota and post-fire habitat specialists.
3. May create low contrast heterogeneity. 3. May reduce high-contrast heterogeneity.
1[135–137].doi:10.1371/journal.pone.0087852.t002
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severity fire regimes historically in ponderosa pine and mixed-
conifer forests of western North America; and (2) How have
mixed-severity fire patterns in these forests changed with fire
exclusion? Consistent with common perceptions and restoration
models applied to these forests, we hypothesized that: (1) forest
age-class diversity was low, reflecting long-term effects of low/
moderate-severity fire regimes (Table 1); and (2) fire exclusion has
led to vegetation changes that have increased the prevalence of
high-severity fire.
Methods
Study AreaFIA and published sources of landscape-scale (area of inference
.25,000 ha) data with inference to pre-settlement fire severity and
forest structure were available from the following regions of
western North America: Baja California, the Sierra Nevada, the
Klamath Region, the eastern Cascades, the northern Rockies, the
central Rockies, and the southwestern USA (Figure 1). We used
ecoregional class III data from the US Environmental Protection
Agency (http://www.epa.gov/wed/pages/ecoregions/level_iii_iv.
htm) to define the Sierra Nevada, Klamath, and eastern Cascades
regions. The Sierra Nevada was split along the distinct crest of the
range into the east and west slopes. The portions of the northern
Cascades east of the crest and the main Cascades within California
were combined into the eastern Cascades. The Modoc Plateau
and eastern Sierra Nevada was also combined with the eastern
Cascades. The northern Rockies were in Idaho and Montana, and
the central Rockies were in Colorado, Wyoming and South
Dakota. The southwestern USA included Arizona and New
Mexico.
The dominant conifer over most of the low- to mid-elevation,
montane forests in these regions is ponderosa pine, often with
lesser amounts of Douglas-fir, white fir (Abies concolor (Gord. and
Glend.) Lindl.), and/or grand fir (A. grandis (Douglas ex D. Don)
Lindl.). In the Sierra Nevada and Klamath regions, ponderosa
pine is common and may be dominant, especially in low-elevation
forests, and mixed-conifer forests generally include components of
ponderosa pine, white fir, Douglas-fir, incense-cedar (Calocedrus
decurrens (Torr.) Florin), sugar pine (P. lambertiana Dougl.),
California black oak (Quercus kelloggii Newb.) and evergreen canyon
live oak (Q. chysolepsis Liebm.). Mid-elevation forests of the Sierra
Nevada and Cascades are often dominated by Jeffrey pine,
ponderosa pine, white fir and sugar pine. Low- to mid-montane
forests of the eastern Cascades are dominated by ponderosa pine
and Douglas-fir, and can include components of white fir, grand
fir (Abies grandis Dougl. ex D. Don.) Lindl.), and western hemlock
(Tsuga heterophylla (Raf.) Sarg). Low- and mid-elevation forests of
the Rocky Mountains are dominated by ponderosa pine and
Douglas-fir. In the northern Rockies, these two dominants may co-
occur with white fir and grand fir, and with western hemlock,
western redcedar (Thuja plicata Donn. Ex D. Don.) and quaking
aspen (Populus tremuloides). Forests of the southwestern U.S. are
heavily dominated by ponderosa pine, with some white fir and
Douglas-fir at middle elevations. Precipitation and temperature
data for each region in this study are provided in Table 3.
Evidence for Historical Mixed-severity Fire Regimes inPonderosa Pine and Mixed-conifer Forests
Rotations of high- and moderate-to high-severity
fire. We summarized rotations for high-severity fire from
published studies with inference to large landscapes
(.25,000 ha) in ponderosa pine and mixed-conifer forest land-
scapes of western NA over a period of 70 or more years. The high-
severity fire rotation is equal to the average interval between high-
severity fire across the affected landscape (Table 1). Additionally,
we summarized other evidence regarding the occurrence of high-
severity fire where rotations could not be calculated, but where
landscape-scale inference regarding the relative importance of
high-severity fire was presented, or where rotations could be
calculated but landscapes were ,25,000 ha or the time period was
,70 years.
Dominant overstory tree age distributions. To assess
successional patterns indicative of mixed- vs. low/moderate-
severity fire regimes, we analyzed US Forest Service Inventory
and Analysis (FIA) stand ages (data available at http://www.fia.fs.
fed.us/tools-data/) by region. These data capture the average age
of the trees dominating the canopy layer in forest stands (stand
age, Table 1) that have been sampled probabilistically, with
inference to more extensive landscapes. Because the dominant
trees in ponderosa pine and mixed-conifer forests may be several
centuries old in the absence of disturbance [e.g., 41,42], we
reasoned that the age of relatively young and intermediate-aged
stands (e.g. ,200 years) reflects the time since a disturbance that
shifted dominance from older to younger trees. The FIA database
indicated that young stands (generally 0–30 years) were initiated
by fire. To determine whether disturbances in other plots were
caused by fire, we evaluated the effects of fire exclusion on rates of
disturbance, as described below. It is not possible to specify the
level of mortality that fire or other disturbances may have caused,
but it is possible to determine the extent to which forests were
dominated by older age classes, which would be consistent with
low2/moderate severity fire, versus stands of more diverse age
classes, consistent with mixed-severity fire.
FIA is a monitoring system based on one permanent, random 1-
ha plot per ,2400 ha across forested lands in the USA. For tree
measurements, the plot area is sub-sampled with four circular plots
of 0.1 ha for large trees and 0.017 ha for smaller trees nested
within the larger tree plots. Diameter at breast height (dbh) and
crown position of each tree and the ring count from cores of the
dominant and co-dominant trees (i.e., the main overstory canopy
layer) of each tree species are measured in each subplot [43]. The
stand-age variable for a ‘‘stocked’’ FIA plot (i.e., one containing
trees of any age) is determined from the average of all ring counts
from subplot samples of dominant and codominant trees in the
size class characteristic of the overstory canopy structure, weighted
by cover of sampled trees, and 8 years are added for estimated
time to grow to breast height (1.4 m) at which cores are sampled.
We selected FIA data from low- to mid-elevation forest types in
Wilderness, Inventoried Roadless Areas, and National Parks to
ensure as best we could that stand initiation was not caused by
commercial harvesting of trees or other land use (Fig. 1). We had
no independent way to confirm that trees were never cut at each
plot location, so we interpret the results assuming only that such
management was of minor importance, given that Wilderness,
Roadless, and National Park designations reflect a lack of past
timber harvesting. We selected lands classified as ‘‘timberlands’’ in
Pacific states’ data sets. In the Rockies and southwestern USA,
where there was no such designation, we selected all areas where
the potential vegetation was considered capable of .10 percent
tree cover.
A small number of plots had different stand ages for different
subplots due to disturbances that affected some, but not all,
subplots. In FIA split-age plots where both plot ages were #100
years, plots were split into two stand ages by FIA if they differed by
as little as 1 year. In split-age plots in which both ages were 100–
199 years old, plots were split into two stand ages if they differed
by as little as 2 years. In split-age plots where both ages were $200
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years, plots were split into two stand ages if they differed by as little
as 15 years. To assess the within plot variability in tree ages, we
calculated the standard deviation of the trees used to age each plot.
We standardized this across the range of stand ages by calculating
the standard deviation of the proportional difference between
stand age, and the individual trees used to determine stand age in
each plot, over the range of stand ages.
We reasoned that, prior to fire suppression, under a low/
moderate-severity fire regime, successional, or age-class diversity,
would be low, while it would be high under a mixed-severity fire
regime. With fire exclusion and greater amounts of uncharacter-
Figure 1. Study area. Dots indicate the general locations of Forest Inventory and Analysis (FIA) plots.doi:10.1371/journal.pone.0087852.g001
Table 3. Mean annual precipitation, and mean summer maximum and minimum temperatures, in ponderosa pine and mixed-conifer forests in each region.
Region*Mean annual precipitation(cm)
Mean maximum temperature,June-August (degrees C)
Mean minimum temperature,June-August (degrees C)
Sierra Nevada 104 23 9
Klamath 196 26 11
Eastern Cascades and Eastern Sierra Nevada 113 21 7
Northern Rockies 88 22 6
Central and Southern Rockies 71 22 6
Southwest 58 27 11
*All values are from PRISM data (http://www.prism.oregonstate.edu/normals/) in each 2 km2 PRISM pixel within which an FIA plot used in the study occurred.doi:10.1371/journal.pone.0087852.t003
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istically severe fire the pattern should reverse in both cases (i.e.
increased age-class diversity in low-severity systems and decreased
diversity in mixed-severity systems). We used a Chi-square test of
proportions [44] to test the null hypothesis that there would be no
difference between the actual distribution of stand ages and the
distribution based on a hypothetical scenario of no fire exclusion.
No effect of fire exclusion would indicate that fire was not a
dominant influence on age class diversity. To create a distribution
of average dominant stand ages by region that would exist in
today’s stands had fire exclusion never occurred, we used the
distribution of plots with stand ages dating from 1889 or before.
This time period was immediately prior to the onset of fire
suppression activities by settlers and government agencies [35,45–
56]. Because the average tree ages are somewhat imprecise, we
binned the data into 40-year age classes for hypothesis testing. In
each region, the present age structure for 80 years during effective
fire suppression (1930–2009) was compared with the age structure
prior to fire suppression (1810–1889). For visual analysis, we
shifted the pre-fire suppression (pre-1890) tree age distributions to
present (i.e., shifting 1810–1849 to 1930–1969, and shifting 1850–
1889 to 1970–2009) to compare with the current age distributions
(see Figure 2). This allows a clear, visual comparison of stand ages
that currently exist with those that would exist had the same fire
regime from 1810–1889 occurred from 1930–2009.
We included only plots where there was one stand age for the
full plot because we wanted to evaluate high-severity fire
occurrence in patches at least 1 ha in size, rather than include
smaller torching of groups of trees. Excluding the split-age plots
(27% of plots in the Sierra Nevada, 40% in eastern-Cascades/
eastern-Sierra, 26% in Klamath, 14% in northern Rockies, 36%
in central/southern Rockies and 14% in southwestern USA) omits
some additional evidence for local high-severity fire effects; thus
our results may be conservative.
We used FIA data drawn from 2001–2009, comprising 90% of
available plots, in our classification of low/mid-elevation forests in
the Sierra Nevada, Klamath, and eastern Cascades. In the other
regions, FIA plots represented 100% of the data from low- to mid-
elevation, montane forests. The number of plots in the 0–39 year
age bins may be slight underestimates of the amount of high-
severity fire in the last 40 years because severe fire could have
occurred subsequent to the sample date (plots were sampled
between 1995–2009 in the northern, central and southern
Rockies, and southwestern USA and 2001–2009 in the Sierra
Nevada, Klamath and eastern Cascades). To estimate the number
of plots that burned severely after the sample date, we increased
the 0–39 year old bin by a factor of 40/36 in the Sierra Nevada,
Klamath and eastern Cascades, 40/34 in the northern Rockies
and 40/32.5 in the central/southern Rockies and southwestern
USA region. The denominator in these weightings is based on 40
Figures 2. Age class distributions of dominant overstory trees. Data are from US Forest Service Forest Inventory and Monitoring plots fromforested areas protected from logging in A. the western (main) Sierra Nevada, B. the Klamath Region, C. the eastern Cascades and Sierra Nevada, D.the northern Rockies, E. the central/southern Rockies, and F. the southwestern USA. Shown in black bars is the current distributions of stand ages.Grey bars show an expected distribution (average age of dominant overstory trees with no fire exclusion), based on projecting the occurrence of thesame age distributions that occurred from 1810–1889 into the most recent 80 year time period and rescaling these data. The number of plots byforest type are shown in the imbedded tables. Non-stocked stands are those lacking trees that grew after the fire that could be aged non-destructively.doi:10.1371/journal.pone.0087852.g002
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minus the mean amount of time in which plots in each region
could have burned after being sampled.
We used year of the recent fire disturbance, captured in the
disturbance data field, to define the age of very young FIA plots
not containing trees that could be aged in a non-destructive way
(FIA surveys do not allow trees to be killed). These ‘‘non-stocked’’
plots were relatively rare, as reported in the results, and ages,
based on fire dates, all fell within the 0–39 age category. Some
non-stocked stands had no disturbance coded. In California,
Oregon, and Washington (Pacific states), disturbances were only
coded if they were ,6 years old. We placed all non-stocked plots
where no disturbance was coded in the database into the 0–39
stand age bin.
Next, we considered whether the age distributions as shaped by
fire were consistent with mixed- or low/moderate-severity fire
regimes. We reasoned that a wide range in the plot stand ages in a
landscape would be consistent with age-class diversity created by
mixed-severity fire, while stand ages that were evenly distributed in
predominantly older age classes would be consistent with a low/
moderate-severity fire regime. To test whether stand age
distributions were consistent with mixed- or low/moderate-
severity fire regimes, we again used a Chi-square comparison of
proportions [44]. Specifically, we tested the probability that the
actual age distributions differed from an expected stand-age
distribution for a low/moderate-severity fire regime. The low/
moderate-severity (expected) distribution was based on 12.5% of
stands falling into each 40-year age class between 80–399 years (0–
319) years at the onset of fire exclusion. Our null hypothesis was
that there would be no significant difference between the actual
and expected (low/moderate-severity) distributions.
Third, we tested, again using a Chi-square comparison of
proportions [44], the hypothesis that there would be less evidence
for historical mixed-severity fire in the generally drier ponderosa
and Jeffrey pine stands than in the mixed-conifer forests (i.e., the
pine forests would be more frequently dominated by older stands).
Results
Evidence for Historical Mixed-severity Fire Regimes inPonderosa Pine and Mixed-conifer Forests
Rotations of high- and moderate- to high-severity
fire. The studies that allow calculation of rotations of high-
severity fire over large, ponderosa pine and mixed-conifer forest
landscapes of western North America over time periods of at least
70 years include areas ranging from 40,700 to 1,193,200 ha
(Table 4). These large landscapes totaled 2.2 million ha in Baja
California, the Sierra Nevada, eastern Cascades, northern Rockies
(Blue Mountains of Oregon), the Colorado Front Range and
Arizona (Black Mesa and the Mogollon Plateau). Most of the
evidence presented in these studies was from ponderosa pine
forests.
The high-severity fire rotations in Table 4 do not support the
hypothesis that low/moderate-severity fire regimes were predom-
inant in the majority of ponderosa pine and mixed-conifer forests
of western North America. In all the large, forest landscapes for
which data covering at least 70 years exist, high-severity fire
rotations ranged from about 217 to 849 years [57], and were
mostly ,200–500 years. This is generally less than potential tree
lifespans. For combined moderate- and high-severity fires in the
eastern Cascades, rotations were 115–128 years (Table 4: [35]),
while they were 249 years in the Colorado Front Range (Table 4:
[58]). In the Blue Mountains (northern Rockies) and on the
Mogollon Plateau in Arizona, high-severity fire rotations of 849
and 828 years, and moderate/high-severity fire rotations of 235
and 319 years, respectively [57], occurred. Where high-severity
rotations are relatively long, as they are in these regions, forest
structure in portions of the landscape will lack evidence for high-
severity fire even though it occurs often enough to create age-class
diversity. Thus, while about 40% of the Blue Mountains forests
and about 62% of those on the Mogollon Plateau had evidence
from GLO surveys of forests shaped by low/moderate-severity fire
only [57], similar to the nearby Coconino Plateau [59], structural
diversity created by high-severity fire was evident on the
remainder of the landscape [57,59].
Numerous other studies that describe historical patterns of fire
behavior also have documented or described evidence for mixed-
severity fire effects in the ponderosa pine and mixed-conifer forests
of western North American, including the occurrence of large
high-severity fire patches (Table S1), and high-severity fire
occurring over substantial areas of smaller landscapes over a time
period of only a few decades prior to fire exclusion (e.g., Klamath
region and a transitional area between the Sierra Nevada and
eastern Cascades [60–63]).
Previous studies (Table 4) have used evidence of past fire
severity from a variety of sources: GLO and other survey data,
historical aerial photos; and mapping of vegetation and burns
done prior to fire exclusion. The GLO analyses have been
formally assessed for accuracy [64]. The methods performed well
for addressing general hypotheses about the presence or absence of
vegetation shaped by low- or high-severity fire. This was tested
using existing vegetation plot data with an error of 14.4–23% [64].
Plot age distributions. A total of 2119 FIA plots represent-
ing a sample population of about 5.1 million ha of unmanaged
low- to mid-elevation, montane forests in six regions (Figure 1,
Table 5) were included in our analysis. Stand ages from ponderosa
pine and mixed-conifer forests across the western USA never
managed for timber cover areas ranging from 192,200 ha in
eastern Cascades-eastern Sierra Nevada to 3,244,800 ha in the
northern Rockies. Average stand ages ranged from 0 to 814 years,
with the oldest stand in ponderosa pine in the eastern Cascades.
The within plot standard deviation of the proportional difference
among individual tree ages and stand age across all plots was 0.14
(e.g., for stands 100 years old, one standard deviation would
include individual trees ,86–114 years old, and two standard
deviations would include trees ,72–128 years old).
The comparison of actual stand ages from 1930–2009 and the
rescaled (expected) stand ages from 1810–1889 assuming no effect
of fire exclusion are shown in Figs. 2A–F. In all regions, there were
highly significant differences between the actual and expected
stand age distributions (average ages of dominant trees with no fire
exclusion) (P,0.001, Fig. 2A–F), indicating that fire was the
predominant disturbance prior to effective fire exclusion. The FIA
database also indicates that, since the onset of fire suppression, the
great majority of stands were initiated by fire. As illustrated by the
abundance of plots with stand ages that date to the decades prior
to fire exclusion (e.g. 80–160 years old presently), much of the
landscapes had young forests, but the rate of establishment
decreased dramatically after 1930 (stand ages ,80 years are rare).
The rate of young forest establishment decreased by a factor of 4
in the Sierra Nevada and southwestern USA, by 3x in the
Klamath, and 2x in the eastern Cascades and central and northern
Rockies.
Chi-square comparisons between actual stand-age distributions
at the onset of fire exclusion versus the expected stand-age
distributions for a low/moderate-severity fire had exceptionally
low probabilities in all regions (P,,.00001, n = 61–877). This was
because plots were mostly dominated by young and intermediate
aged trees prior to fire exclusion (Figs. 2A–F). The mean stand
Mixed-Severity Fire in Drier Conifer Forests
PLOS ONE | www.plosone.org 7 February 2014 | Volume 9 | Issue 2 | e87852
Ta
ble
4.
Ro
tati
on
sfo
rh
igh
-se
veri
tyan
dm
od
era
te-s
eve
rity
fire
inlo
w/m
id-e
leva
tio
nco
nif
er
fore
sts
of
we
ste
rnN
ort
hA
me
rica
.
Re
gio
nL
oca
tio
nS
ou
rce
An
aly
sis
are
a(h
a)
Fo
rest
typ
es
Tre
em
ort
ali
tyT
ime
pe
rio
dA
pp
rox
ima
tero
tati
on
(ye
ars
)
Pac
ific
stat
es
No
rth
ern
Baj
aC
alif
orn
ia[1
18
]1an
alys
iso
fae
rial
ph
oto
s4
0,7
00
Mix
ed
con
ife
ran
dJe
ffre
yp
ine
.9
0%
ove
rsto
rym
ort
alit
y1
92
5–
19
91
30
0
No
rth
ern
Sie
rra
Ne
vad
a[5
1]2
Gro
un
dsu
rve
ysan
dd
eta
iled
map
s1
46
,91
7M
ixe
dco
nif
er,
do
min
ate
db
yp
on
de
rosa
pin
e7
5%
mo
rtal
ity
by
volu
me
was
map
pe
dfo
rp
atch
es
.3
2.4
ha
18
00
–1
90
04
88
East
ern
Cas
cad
es
(Was
hin
gto
n)
[17
,35
]3,
4A
nal
ysis
of
his
tori
cal
aeri
alp
ho
tos
17
5,2
00
Mix
ed
con
ife
ran
dp
on
de
rosa
pin
e.
70
%tr
ee
mo
rtal
ity6
,1
83
0–
19
30
37
9–
50
5
.2
0%
tre
em
ort
alit
y6,
18
30
–1
93
01
15
–1
28
East
ern
Cas
cad
es
(Ore
go
n)
[56
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
12
3,5
00
Po
nd
ero
sap
ine
.7
0%
tre
em
ort
alit
y7,
17
68
–1
88
27
05
14
0,4
00
Dry
mix
ed
con
ife
r.
70
%tr
ee
mo
rtal
ity7
,1
76
8–
18
82
49
6
No
rth
ern
Ro
ckie
sO
reg
on
(Blu
eM
ou
nta
ins)
[57
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
30
4,7
00
Po
nd
ero
sap
ine
fore
sts
.7
0%
tre
em
ort
alit
y7,
17
40
–1
88
08
49
Ore
go
n(B
lue
Mo
un
tain
s)[5
7]5
An
alys
iso
fG
en
era
lLa
nd
Off
ice
surv
ey
dat
a3
04
,70
0P
on
de
rosa
pin
efo
rest
sM
od
era
te-
and
hig
h-s
eve
rity
fire
,1
74
0–
18
80
23
5
Ce
ntr
alR
ock
ies
Ce
ntr
al(C
olo
rad
oFr
on
tR
ang
e)
[57
,73
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
65
,50
0P
on
de
rosa
pin
efo
rest
s.
70
%tr
ee
mo
rtal
ity7
,1
70
5–
18
80
27
1
Ce
ntr
al(C
olo
rad
oFr
on
tR
ang
e)
[58
]8A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
62
4,1
56
Mo
stly
po
nd
ero
sap
ine
and
Do
ug
las-
fir
Mo
de
rate
and
hig
h-
seve
rity
fire
18
09
–1
88
32
49
Sou
thw
est
(Ari
zon
a)B
lack
Me
sa[5
7]5
An
alys
iso
fG
en
era
lLa
nd
Off
ice
surv
ey
dat
a1
51
,10
0P
on
de
rosa
pin
efo
rest
s.
70
%tr
ee
mo
rtal
ity7
,1
76
0–
18
80
21
7
Mo
go
llon
Pla
teau
[57
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
45
2,1
00
Po
nd
ero
sap
ine
fore
sts
.7
0%
tre
em
ort
alit
y7,
17
60
–1
88
08
28
Mo
go
llon
Pla
teau
[57
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
45
2,1
00
Po
nd
ero
sap
ine
fore
sts
Mo
de
rate
-an
dh
igh
-se
veri
tyfi
re,
17
60
–1
88
03
19
Bla
ckM
esa
and
Mo
go
llon
com
bin
ed
[57
]5A
nal
ysis
of
Ge
ne
ral
Lan
dO
ffic
esu
rve
yd
ata
60
3,2
00
Po
nd
ero
sap
ine
fore
sts
.7
0%
tre
em
ort
alit
y7,
17
60
–1
88
05
22
Dat
afr
om
Ge
ne
ral
Lan
dO
ffic
eo
rm
app
ed
dat
ao
ver
larg
ear
eas
(.2
5,0
00
ha)
ove
r.
70
or
mo
reye
ars
pri
or
tofi
ree
xclu
sio
n.
1St
ud
yar
ea
was
do
min
ate
db
ym
ixe
dco
nif
er
and
Jeff
rey
pin
ean
dm
inim
ally
log
ge
d.F
ire
exc
lusi
on
on
lyb
eg
anin
the
19
70
san
dh
ash
ado
nly
am
od
est
imp
act
[13
8].
Th
us,
his
tori
cala
nd
curr
en
tra
tes
are
assu
me
dto
be
com
par
able
.2A
nal
ysis
of
Leib
erg
’sm
app
ing
of
hig
h-s
eve
rity
fire
are
asw
ith
inu
nlo
gg
ed
mix
ed
-co
nif
er
Sie
rran
stan
ds
isfo
un
din
[13
9].
Acc
ord
ing
toLe
ibe
rg[5
1],
mo
stsu
chfi
reo
ccu
rre
dp
rio
rto
18
50
.In
add
itio
n,h
est
ate
d‘‘I
fth
em
any
smal
llo
ts[,
32
ha]
scat
tere
dth
rou
gh
ou
tst
illg
row
ing
stan
ds
we
reta
ken
into
acco
un
t,th
efi
gu
re[a
mo
un
to
far
ea
bu
rne
dse
vere
ly]
wo
uld
be
con
sid
era
bly
incr
eas
ed
.’’3T
he
nu
me
rato
rw
ase
stim
ate
dat
10
0ye
ars
bas
ed
on
po
nd
ero
sap
ine
inth
isre
gio
n[1
40
],w
ho
seg
row
thw
ou
ldsu
rpas
s3
0cm
db
h,r
en
de
rin
gm
ixe
dan
dh
igh
-se
veri
tye
ffe
cts
ind
isti
ng
uis
hab
le(s
ee
[35
:Tab
le1
]).T
his
calc
ula
tio
nis
con
serv
ativ
eb
eca
use
tre
eg
row
thto
30
cmd
bh
inm
ois
ter
fore
sts
isfa
ste
rth
an1
00
year
s.4H
igh
-an
dm
ixe
d-s
eve
rity
fire
con
sist
en
tw
ith
ad
efi
nit
ion
of
.7
0%
and
20
–7
0%
bas
alar
ea
mo
rtal
ity,
resp
ect
ive
ly,
was
ide
nti
fie
dfr
om
ove
rsto
ryca
no
py
pe
rce
nta
ge
,th
eo
vers
tory
size
clas
s,th
eu
nd
ers
tory
size
clas
s,an
dth
efi
reto
lera
nce
of
the
cove
rty
pe
(se
e[3
5:
Tab
le1
]).
Larg
ep
atch
size
so
fh
isto
rica
lh
igh
seve
rity
fire
(10
0s
to.
50
00
ha)
fro
mth
isw
ork
are
rep
ort
ed
in[1
7].
5T
he
est
imat
eis
fro
mth
esp
ano
fye
ars
ove
rw
hic
hfi
ree
ffe
cts
we
red
isti
ng
uis
hab
le,
usi
ng
fore
stst
ruct
ure
evi
de
nt
inth
eG
ove
rnm
en
tLa
nd
Off
ice
his
tori
cal
surv
ey
dat
a,d
ivid
ed
by
the
frac
tio
no
fth
efo
rest
ed
lan
dsc
ape
inw
hic
hth
ose
fire
so
ccu
rre
d[5
6].
Ro
tati
on
sfo
rh
igh
-se
veri
tyfi
rear
ed
ete
rmin
ed
by
div
idin
gth
eo
bse
rvat
ion
pe
rio
d(t
he
pe
rio
do
fti
me
ove
rw
hic
hfi
ree
ffe
cts
are
dis
tin
gu
ish
able
by
stan
dst
ruct
ure
)b
yth
ep
erc
en
tag
eo
fth
ela
nd
scap
ee
xpe
rie
nci
ng
hig
h-s
eve
rity
fire
.T
he
me
tho
ds
we
refo
un
dto
hav
e1
4.4
–2
3%
accu
racy
com
par
ed
top
lot
sam
plin
g.
6H
igh
-an
dm
ixe
d-s
eve
rity
fire
,co
nsi
ste
nt
wit
ha
de
fin
itio
no
f.
70
%an
d2
0–
70
%,r
esp
ect
ive
ly,w
ere
ide
nti
fie
dfr
om
ove
rsto
ryca
no
py
pe
rce
nta
ge
,th
eo
vers
tory
size
clas
s,th
eu
nd
ers
tory
size
clas
s,an
dth
efi
reto
lera
nce
of
the
cove
rty
pe
(se
e[3
5:
Tab
le1
]).
7H
igh
-se
veri
tyco
nsi
ste
nt
wit
ha
de
fin
itio
no
f.
70
%b
asal
are
am
ort
alit
y[3
5]
was
ide
nti
fie
dh
avin
ga
pe
rce
nta
ge
of
smal
ltr
ee
s.
50
%an
da
pe
rce
nta
ge
of
larg
etr
ee
s,
20
%[5
6,5
7,7
3],
8Es
tim
ate
dfr
om
the
len
gth
of
Ge
ne
ral
Lan
dO
ffic
ese
ctio
nlin
es
inte
rce
pte
db
ym
od
era
te-
and
hig
h-s
eve
rity
fire
.A
ccu
racy
test
su
sin
gth
ele
ng
tho
fse
ctio
nlin
es
inte
rce
pte
db
ym
od
ern
mo
de
rate
-an
dh
igh
-se
veri
tyfi
reyi
eld
ed
are
lati
vee
rro
ro
f1
5.6
%.
do
i:10
.13
71
/jo
urn
al.p
on
e.0
08
78
52
.t0
04
Mixed-Severity Fire in Drier Conifer Forests
PLOS ONE | www.plosone.org 8 February 2014 | Volume 9 | Issue 2 | e87852
ages at the time of onset of fire exclusion were 59–114 years,
depending on the region, considerably shorter than current mean
ages (105–148 years: Table 5). Therefore, the FIA data were
inconsistent with the hypothesis that the ponderosa pine and
mixed-conifer forests of western North America, in unmanaged
landscapes, were predominantly park-like with low age-class
diversity due to the dominant influence of low/moderate-severity
fire.
The hypothesis that mixed-severity fire prior to fire exclusion
would be lower in the driest (ponderosa and Jeffrey pine) forests
than other forests also was not supported. Based on stand-ages (not
shown), there was as much as or more mixed-severity fire in the
pine forests. In the Pacific states, we found almost identical stand-
age distributions from 1800–1900 in ponderosa/Jeffrey pine
stands (n = 20 plots) versus all non-ponderosa stands (n = 204
plots). Plots from the time period 1800–1900 accounted for 70%
and 73%, respectively, of all plots with dominant trees that
established in or before 1900. In the northern and central Rockies,
86% of ponderosa pine stands (n = 66 plots) and 81% of the non-
ponderosa pine stands (n = 615 plots) that established in or before
1900 had stand-ages between 1800 and 1900 (x2 = 0.85, n = 676,
P.0.6). Likewise, in the southwestern USA, 98% of ponderosa
pine stands (n = 96 plots) and 92% of the non-ponderosa stands
(n = 37 plots) that established in or before 1900 had stand-ages
between 1800 and 1900 (x2 = 1.27, n = 133, P.0.25). However,
when all plots were considered, significantly more stands
established from 1800–1900 in ponderosa pine than non-
ponderosa forests (x2 = 11.96, n = 1038, P,0.001), indicating
higher fire disturbance in pine forests.
Comparing the Weight of Landscape-scale Evidence byRegion
The consistency of multiple lines of evidence for mixed-severity
fire in the ponderosa pine and mixed-conifer forests is an
important finding. In all regions, there were tree-age data
supporting considerable age-class diversity created by mixed-
severity fire, and a paucity of undisturbed park-like forests. The
full weight of landscape-scale evidence is greatest in the regions
with area-specific rotations of severe fire from GLO data: the
eastern Cascades, nearby Blue Mountains in the northern Rockies,
central Rockies, and southwestern USA (Table 4). In the
Cascades, these data are further supported by analyses of early
aerial photography at a regional scale [35], and in small
landscapes [61–63] and numerous historical descriptions (see
[56]: Table S1). In the northern Rockies, historical documentation
(e.g., [45–48,50,53,54]) of mixed-severity regimes has been
summarized in regional reviews [16,65,66], and stand-age
reconstructions of historical fire regimes indicate mixed-severity
fire in ponderosa-pine/Douglas-fir forests [67–69]. In the Colo-
rado Front Range, the findings based on GLO data [57,58] are
remarkably consistent with earlier studies based on tree-ring stand
reconstructions from broadly distributed samples [70–72]. In the
Table 5. Forest Inventory and Analysis (FIA) data.
Region
Number of plots (n) andforest area randomlysampled (ha) Mean FIA stand age (yrs)
Test for difference in stand initiation since1930 vs. 1800–1900: Chi-square, P
Current In 1930
Sierra Nevada (main) n = 232 338,400 148 97 86.3, ,,0.001
E. Cascades and E. Sierra Nevada n = 135 192,000 155 114 25.4, ,,0.001
Klamath Mountains n = 251 372,000 157 111 43.9, ,,0.001
Central Rockies n = 276 446,400 105 75 58.9, ,,0.001
Northern Rockies n = 1929 3,244,800 105 70 333.8,,0.001
Southwestern US n = 319 492,000 116 59 188.2,,0.001
Area of sample population randomly sampled, mean stand age currently, and in 1930, and Chi-square test results.doi:10.1371/journal.pone.0087852.t005
Table 6. Current high-severity fire rotations.
Region Source Forest Types Time period Rotation (yrs)
Sierra Nevada, southern Cascades [132] All low/mid- and mid/upper elevationconifer forests
1984–2010 645
Klamath (all) [129] All low/mid-elevation conifer forests 1984–2005 599
Eastern Cascades (all) [129] All low/mid-elevation conifer forests 1984–2005 889
Northern Rockies [92] Ponderosa pine forests 1980–2003 500
Central Rockies [92] Ponderosa pine forests 1980–2003 714
Central Rockies [58] Ponderosa pine forests 1984–2009 4311
Southwest [92] Ponderosa pine forests 1984–2003 625
Northwest (Eastern Cascadesand Blue Mountains)
[92] Ponderosa pine 1984–2003 1,000
Data cited are from low/mid-elevation conifer forests in western North America.1Higher-severity fire: includes moderate- and high-severity.doi:10.1371/journal.pone.0087852.t006
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southwestern USA, GLO data are supportive of mixed-severity
fire on most of Black Mesa and much of the Mogollon and
Coconino Plateaus [57,59], while a number of other studies also
describe evidence for mixed-severity fire [9,14,55,73–77].
The remaining forest regions that we assessed lack GLO
analyses. However, in the Sierra Nevada and Klamath regions
historical surveys and early air photo data describe mixed-severity
fire regimes [20,30,49,51,60,78–87] (see Table S1 for descrip-
tions). In all regions except the Klamath, there are multiple lines of
evidence from landscape-scale studies, each supporting mixed-
severity fire. In contrast, evidence supporting low/moderate-
severity fire is confined to relatively small areas (e.g., [88–91]).
Historic vs. Contemporary Fire RegimesWe did not find evidence to support the hypothesis that fire
exclusion has greatly increased the prevalence of severe fire in
ponderosa pine and mixed-conifer forests (Tables 4–6, and
Figs. 2A–F). Comparing current versus historical high-severity
fire rotations, we found that current rotations were generally
longer (less high-severity fire) in the Sierra Nevada and central
Rockies (Tables 4 and 6, Table S1). No direct historical
comparison could be made between current and historical high-
severity rotations in the Klamath and northern Rockies at the
spatial scale required in Table 4, but evidence presented in Table
S1 suggests that current rotations of 599 years and 500 years,
respectively, may be longer. The estimated rotation of 625 years
for recent high-severity fire in the southwestern USA [92] was
shorter than the historical estimate of 828 years for the Mogollon
Plateau in Arizona. Combining the Mogollon Plateau and Black
Mesa to provide a better comparison with fire across the
southwestern USA produces a historical high-severity rotation of
522 years [57]. In the eastern Cascades, high-severity fire rotations
since 1984 (889 years) were longer than historical rotations
(Table 6 vs. Table 4).
Discussion
Historical Fire RegimesThe primary objective of this paper was to address how
prevalent mixed-severity fire regimes were historically in ponder-
osa pine, mixed conifer, and other low- to mid- elevation, montane
forests of western North America. We hypothesized that age-class
diversity was low, consistent with long-term effects of low/
moderate-severity fire regimes (Table 1). We reviewed evidence
with inference across both large and smaller landscapes across
many forest regions. The majority of the evidence did not support
the low/moderate-severity fire hypothesis, but, instead, supported
the alternate hypothesis that mixed-severity fire shaped these forest
landscapes. This finding applies to Pacific states ponderosa pine,
Jeffrey pine, and California mixed-conifer forests, as well as
ponderosa pine and mixed-conifer forests in the eastern Cascades,
Rockies and southwestern USA, where low/moderate-severity
regimes have often been applied. In some areas (Blue Mountains,
Mogollon and Coconino Plateaus) high-severity fire occurred at
less frequent intervals (rotations of 828–849 years) [57,59]. Even at
these rotations, high-severity fire creates considerable age-class
diversity in a landscape, and moderate/high-severity fire rotations
were 235–319 years, which further enhances diversity (with small
groupings of high-severity fire interspersed within moderate-
severity fire areas).
FIA stand ages in the unmanaged forests in all regions reflect a
pattern of high age-class diversity occurring prior to federal fire
suppression policies and reductions in Native American burning
(by the early 20th century) with the arrival of settlers [20,46,49,51]
Natural disturbances occurred at rates that led to stands
numerically dominated mainly by young and intermediate-aged
trees. Disturbance processes dramatically declined following the
onset of fire exclusion, suggesting fire was the primary disturbance
agent [35]. However, in considering the age patterns of dominant
trees in the FIA plots, it is essential to also address alternative
explanations for the dominance of young- and intermediate-aged
stands prior to fire exclusion, such as climate variability and
disturbance by insect outbreaks.
While we recognize that climate variability influences rates of
tree regeneration generally [93], and may determine success or
failure of tree regeneration specifically following disturbance, we
believe that the broad patterns of dominant overstory tree ages in
the FIA plots mainly reflect the effects of past fire for several
reasons. The dominant stand ages of young and intermediate aged
trees prior to fire exclusion are consistent with periodic distur-
bances with significant tree mortality that shifted dominance to a
new generation of trees, rather than solely episodic tree
establishment due to climatic variation at a multi-decadal scale.
This is supported by research in the central Rockies where, at a
multi-decadal time scales, large datasets of tree recruitment dates
over the past c. 250 years do not correlate with moister climate at
the same time scale, but instead correlate with drier climate that
was conducive to high-severity fires [70–72,91]. Likewise, studies
in the same area show that outbreaks of bark beetles and
defoliators result in growth releases of non-host trees rather than
even-aged, multi-species tree cohorts [94,95], thus facilitating
discrimination from post-fire stand structures [91]. Fire exclusion
was likely effective in some areas between 1900 and 1930, which
could have led to understory tree recruitment in this time frame.
However, research suggests that in some areas the favorable
influences of timber harvesting and/or cattle grazing on tree
establishment may confound the attribution of tree recruitment to
fire exclusion [96]. In addition, the plot age data demonstrate that
recruitment was just as common or more common in decades
before 1900 as between 1890 and 1930. Lastly, while it is possible
that greater mortality in older trees, from competition or insects
and pathogens, might explain high levels of recruitment prior to
fire exclusion, we do not see this pattern during the suppression
era. Thus, higher levels of mortality in older trees seems likely to
have been caused by fire.
Our findings illustrate the need for studies with a spatial scale of
inference suited to describing patterns across large, heterogeneous
landscapes. This is illustrated by three recent studies from old
forest stands (one in the Black Hills (500 ha), one in the Sierra
Nevada (3,000 ha), and one in the southwestern USA (307 ha))
that reported very little or no historical high-severity fire, and
hence low-severity regimes (Table S1: [88–90]). In contrast,
broader-scale analyses of historical data for the Sierra Nevada
(Table S1: [78]:), Black Hills [65], and southwestern USA [57]
suggest fire regimes in the broader landscape within which these
three studies occurred were mixed-severity.
A fourth study [97] analyzed 1914–1922 Bureau of Indian
Affairs (BIA) timber cruise plot data from within a larger area
(38,651 ha), and found relatively low tree densities in ponderosa
pine and mixed-conifer forests of the eastern Klamath region in
Oregon, and suggested that forests were too open to support any
significant crown fire. However, only a subset of the townships
surveyed by BIA in these forest types were included in the analysis
(Table S1), and the surveys did not include trees 10–15 cm dbh,
which comprise ,20% of all trees [97], and most surveys did not
include lodgepole pine, which comprise ,10% or more of these
forest types in that region within unlogged areas [49]. In addition,
historical data indicate that extensive timber harvesting had
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PLOS ONE | www.plosone.org 10 February 2014 | Volume 9 | Issue 2 | e87852
occurred in the areas analyzed by 1914–1922 (Table S1), and
evidence of previous timber harvesting was not among the factors
that BIA surveyors were required to note (Table S1). Tree
densities in unlogged reference ponderosa pine and mixed-conifer
forests in this landscape from the late 19th century and early 20th
century indicate much denser and more variable forest conditions
(Table S1). Also, USGS surveys conducted in the 1890s within
unlogged ponderosa pine and mixed-conifer forests across a larger
expanse (310,267 ha) map substantial high-severity fire from
1855–1900 (high-severity rotation of 352 years), suggesting a
mixed-severity regime (Table S1).
The absence of evidence for mixed-severity fire in some older
forests selected for study may be due to fire exclusion. If the effect
of fire exclusion in reducing mixed-severity fire is not accounted
for in describing reference conditions, it may lead to shifting
baseline syndrome (i.e., a system is not measured against the true
baseline, but against one that already has departed from the true
baseline [98]). This effect may be caused or compounded by
diminishing evidence of age-class diversity. For example, high-
severity fire can be mapped at landscape scales from early air
photos [9,17,61–63,99], but the same historic fire effects may not
be visible from current imagery that can be used for assessing
landscape-scale patterns.
Data with greater temporal depth than analyzed here can better
capture past variability in the frequency of large fire events. Thus,
it is noteworthy that paleoecological studies also support mixed-
severity fire regimes for the ponderosa pine and mixed-conifer
forests. These studies have found charcoal depositions from major
fire episodes in ponderosa pine and interior Douglas-fir forests
occurring for millennia in the northern Rockies (central Idaho:
[100,101]), Klamath [102], Sierra Nevada [103], eastern Oregon
Cascades [104], and southwestern USA [105–107]. These major
episodes are generally interpreted as large, severe fire events [101–
107].
The occurrence of mixed-severity fire prior to fire exclusion is
also well supported by another line of evidence: the potential
behavior of wildfire as affected by weather and climate. Based on
direct observations of fire behavior, high winds (generally 10 m
open wind speeds .32–35 kilometers/hr) may subject virtually
any conifer forest, regardless of fuel density, to crown fire [108].
Thus, empirical data call into question a major premise of the
low/moderate-severity fire regime: that ponderosa pine and
mixed-conifer forests may be completely resistant to crown fire.
Fire intensity increases with winds, and at winds of .30 km/hr
spot fires may be ignited over 1 km ahead of the fire front [109].
The coalescing of separate spot fires with the fire front can further
energize wind-driven fire [110,111]. Severe droughts also intensify
fires by reducing fuel moisture to extremely low levels, allowing
crown fire under less windy conditions [108,112]. Severe drought
years throughout much of western North America occurred from
1856 to 1865, 1870 to 1877 and 1890 to 1896 [113]. The
extensive high-severity fires of 1910 (the Big Burn in Idaho and
Montana), when large areas of drier forests burned at high severity
prior to fire exclusion–much of it in ponderosa pine–illustrate how
fire behavior that is rare temporally due to extreme climate and
weather can dominate in space [1]. Many fire episodes in the
charcoal records that exceed modern fires undoubtedly involve
combinations of extreme wind, drought, and mass fire.
The largest patch sizes of high-severity fire likely occurred
during the most extreme conditions for fire behavior. While patch
sizes of high-severity fire are difficult to document, it follows from
commonly observed heavy-tailed distributions of patch sizes
created by fire [114,115] that very large patches of high-severity
fire (thousands of ha, e.g., [17: Fig. 1, 58]) were a primary reason
why considerable area exhibited forest structure consistent with
high-severity fire historically in all regions. Large patches, though
numerically subordinate, are dominant in terms of total area
burned, while the opposite applies to small patches [58].
There is abundant evidence that past forests may not have
required extreme weather and climate for mixed-severity fire to
have occurred. Younger, more flammable forests [32] appear to
have been widespread in dry-forest regions based on dominant
stand ages prior to fire exclusion (Fig. 2). In addition, the ranges in
fire-free intervals in many low- to mid-elevation forested areas
were sufficient to allow for substantial vegetation growth and
recovery of fuels between fires (e.g., 20–50+ year rotations [61–
63,116–118]). For example, in the Sierra Nevada, fuels may
recover to pre-burn levels in nine years [119,120], so fire-free
interludes (or fire rotations), more often than not, may have been
sufficient to allow growth of significant amounts of high-energy
shrub fuels. In describing low/mid-elevation forests throughout
the northern Sierra Nevada, Leiberg [51: page 32) states: ‘‘There
is a great amount of undergrowth in the forest which has attained
its present proportions chiefly through the agency of fire. Most of it
[undergrowth] consists of species of Ceanothus.’’ For mid-elevation
forests, he reports (page 37): ‘‘Nearly all the type situated at
altitudes below 7,000’ [2134 m] carries a vast amount of
undergrowth. It consists mainly of manzanita [Arctostaphylos spp.],
ceanothus, and scrub oak [Quercus chrysolepis, Q.vaccinifolia].’’
Similarly abundant shrub fuels were also documented historically
in the westside of the central/southern Sierra Nevada [51], in the
eastern Oregon Cascades [56: Appendix A] and in Oregon’s Blue
Mountains [57]. Flame lengths in actively burning manzanita and
ceanothus are typically 4–5 times the ,1–2 m height of the
shrubs, sufficient to cause ignition of forest canopy tree crowns
under favorable burning conditions. Many of these shrub species
recruit primarily, if not exclusively, after severe fire, and their
occurrence is a further indication of the historical presence of such
fire [121].
Changes in Fire Regimes and Stand Age Distributionswith Fire Exclusion
We also hypothesized, consistent with existing concerns about
unprecedented fire severity in western North America (e.g., [6–
9,11,13,15,17,28]), that fire exclusion has greatly increased the
prevalence of severe fire in ponderosa pine and mixed-conifer
forests. We found little support for this hypothesis. Over the full
period of effective fire exclusion in unmanaged forests, average
ages of dominant overstory trees in FIA plots suggest there has
been about a threefold to fourfold decrease in stand initiation due
to fire in the Sierra Nevada, Klamath, and southwestern USA, and
about a twofold decrease in the eastern Cascades, central and
northern Rockies (Figs. 2A–F). In addition, patch sizes of high-
severity fire in the central Rockies have not increased [58]. Our
assessment of high-severity rotations based upon existing literature
also revealed a generally lower incidence of high-severity fire in
these forests in recent decades (Tables 4 and 6, and S1).
Conclusion
The importance of multiple lines of evidence has been stressed
in determining whether mixed-severity fire regimes applied
historically [122]. Our results illustrate broad evidence of mixed-
severity fire regimes in ponderosa pine and mixed-conifer forests of
western North America. Prior to settlement and fire exclusion,
these forests historically exhibited much greater structural and
successional diversity than implied by the low/moderate-severity
model (Table 2). Lack of recognition of past variability in fire may
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PLOS ONE | www.plosone.org 11 February 2014 | Volume 9 | Issue 2 | e87852
be due, in part, to common misclassifications of fire regimes. To
improve clarity in communication, we propose that ‘‘low/
moderate-severity’’ be applied to those regimes where, as the
term implies, high-severity fire is absent. These circumstances
appear to be quite rare in the ponderosa pine and mixed-conifer
forests of western North America. Therefore, a fire regime with a
high-severity component of any amount should not be classified as
low/moderate-severity [e.g., 9,17,28].
Our findings suggest a need to recognize mixed-severity fire
regimes (Table 2) as the predominant fire regime for most of the
ponderosa pine and mixed-conifer forests of western North
America. Given societal aversion to wildfires, the threat to human
assets from wildfires, and anticipated effects of climate change on
future wildfires, many will question the wisdom of incorporating
historical mixed-severity fire into management goals. However,
focusing fire risk reduction activities adjacent to homes is needed
to protect communities [123], and this may expand opportunities
for managed wildland fire–away from towns–for ecological
benefits of fire-dependent biota. However, a major challenge lies
with the transfer of information needed to move the public and
decision-makers from the current perspective–that the effects of
contemporary mixed-severity fire events are unnatural, harmful,
inappropriate and more extensive due to fire exclusion–to
embrace a different paradigm [124]. This paradigm would not
emphasize a single, appropriate condition, but would explicitly
recognize the vital role of variation in fire in maintaining
successional diversity and fire-dependent biota [125], and allow
natural rates of ecological succession [18,19,126–128]. It would
also recognize that these effects have generally diminished, and
that more fire, including high-severity fire, where it is in deficit, is
an ecologically desirable goal. Of course, while most current
research indicates that fire severity is not increasing in ponderosa
pine and mixed-conifer forests of western North America [129–
132], it will be critical to continually assess fire regimes in a
changing climate.
For management, perhaps the most profound implication of this
study is that the need for forest ‘‘restoration’’ designed to reduce
variation in fire behavior may be much less extensive than implied
by many current forest management plans or promoted by recent
legislation. Incorporating mixed-severity fire into management
goals, and adapting human communities to fire by focusing fire
risk reduction activities adjacent to homes [123], may help
maintain characteristic biodiversity, expand opportunities to
manage fire for ecological benefits, reduce management costs,
and protect human communities.
Supporting Information
Table S1 Evidence of historic fire severity in ponderosapine and mixed-conifer forests of western North Amer-ica. A summary of published studies and historical documents
that provide evidence regarding mixed-severity fire in the
ponderosa pine and mixed-conifer forests of western North
America, but do not provide sufficient information to estimate
high-severity fire rotations, or were conducted in smaller
landscapes. Many fire scar studies have also been done in these
forests, but fire scars alone are not sufficient to distinguish low-
from mixed-severity regimes.
(DOCX)
Acknowledgments
We thank the reviewers, and we thank Tim Sinnott from GreenInfo
Network for the GIS analysis.
Author Contributions
Conceived and designed the experiments: DCO CTH. Performed the
experiments: DCO CTH AA WLB DAD RH WK MAM RS TTV MAW.
Analyzed the data: DCO CTH AA WLB DAD RH WK MAM RS TTV
MAW. Wrote the paper: DCO CTH AA WLB DAD RH WK MAM RS
TTV MAW.
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